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Glutamate receptor-interacting protein

August 20, 2023

Glutamate receptor-interacting protein (GRIP) refers to either a family of proteins that bind to the glutamate receptor or specifically to the GRIP1 protein within this family. Proteins in the glutamate receptor-interacting protein (GRIP) family have been shown to interact with GluR2, a common subunit in the AMPA receptor.[1] This subunit also interacts with other proteins such as protein interacting with C-kinase1 (PICK1) and N-ethylmaleimide-sensitive fusion protein (NSF). Studies have begun to elucidate its function; however, much is still to be learned about these proteins.

Discovery and history of GRIP 1

 
Binding of GRIP1 to AMPA Receptors

The discovery of the Glutamate Receptor Interacting Protein (GRIP-1) came as a result of the observation that Glutamate Receptors, such as the NMDA receptor, cluster at synapses.[2] Shortly after this observation, researchers identified a region on the C-terminal region of NMDA receptors called the tSXV motif that has the ability to bind to the PDZ domain of the PSD-95 protein.[3]

Research on NMDA receptor localization paved the way for research on non-NMDA receptors such as AMPA receptors. Similar to NMDA receptors, it was discovered that AMPA receptors localize in the synaptic terminal of neurons in the central nervous system.[4] By using GFP (green fluorescent protein) antibodies that correspond to the GRIP protein, researchers were able to use fluorescence to determine the location of GRIP in hippocampal neurons. Another GFP antibody was then used to label the GluR2 subunit of AMPA receptors.[4] By using immunocytochemistry and comparing the location of GRIP and AMPA receptors it was determined that GRIP and AMPA receptors experience colocalization in hippocampal neurons.[4] These findings confirmed the initial hypothesis that the GRIP protein plays an important role in binding AMPA receptors to excitatory synapses.

The structure of GRIP contains seven PDZ domains and binds to the C-terminus of the GluR2 subunit of AMPA receptors.[4] Although the number of PDZ domains is different for the proteins PSD-95 and GRIP, the PDZ domain is a common structural motif in proteins that help mediate protein-protein interactions.[5] The AMPA receptor amino acid sequence that the GRIP protein binds to is ESVKI. The conserved serine amino acid in the C- terminus of both AMPA and NMDA receptors suggests that it plays an important role in facilitating the interaction for GRIP and PSD-95.[6]

Role of GRIP in AMPAR cycling

AMPA receptors are constantly being transported between the cell membrane and intracellular space and it was originally thought that GRIP may be responsible for the clustering of AMPA receptors at the excitatory synapse.[1] Although it is still unclear the exact role of GRIP in this trafficking, It appears that PICK1 is more directly responsible for the clustering of AMPA receptors at the surface and that GRIP is involved in the stabilization of AMPA receptors intracellularly.[7] One study showed that when the interaction between GluR2 and GRIP is disrupted, there are no changes in the surface expression of AMPA receptors or the constitutive internalization of AMPA receptors.[8] There is, however, a reduced amount of receptors that remain internalized when receptor cycling is modified by application of AMPA-1. The ratio returns to normal when constitutive recycling is allowed to happen, suggesting that the stabilization of intracellular receptors is critical only under AMPA-induced internalization.[8]

 
Illustration of roles of GRIP1a and GRIP1b in AMPAR cycling

In later studies, two proteins, GRIP-1 (often reduced to GRIP) and ABP-L (also named GRIP-2), were found to be expressed by two separate genes and their respective contributions to AMPA receptor cycling have since been well studied. Each of these proteins have different isoforms due to differential RNA splicing.[9][10] The isoforms of GRIP-1 are named GRIP-1a and GRIP-1b while those of ABP-L are distinguished as ABP-L and pABP-L. The apparent difference in both cases is that one isoform (GRIP1b and pABP-L respectively) is capable of being conjugated with Palmitic acid, an action called Palmitoylation.

Whereas GRIP initially was thought to be involved in the stabilization of AMPA receptors either at the cell surface or intracellularly when internalization was triggered by AMPA stimulation, it now appears that the GRIP-1 isoforms are involved differentially with the stabilization of AMPA receptors after being internalized due to NMDA stimulation.[11] GRIP-1a has been shown to reduce the expected intracellular levels of AMPA receptors after NMDA stimulation. Conversely, GRIP-1b increases intracellular levels of AMPA receptors under the same conditions.

ABP-L, like GRIP-1b, associates with intracellular stores of AMPA receptors. pABP-L, however, associates with AMPA receptors as the surface membrane.[12] It has not yet been shown under what conditions these interactions are significant in the cycling of AMPAR.

Role of GRIP1 in Fraser syndrome

 
This diagram depicts the role GRIP1 plays in localizing extra-cellular matrix proteins Fras1 and Frem2 at the dermo-epidermal junction.

Mutations to GRIP1 play a role in less than 10% of confirmed cases of the group of congenital defects known as Fraser syndrome.[13] Using immunofluorescence, it has been shown that GRIP1 is found in several kinds of embryonic tissues, including the GI tract, ureter buds, skin and oral and nasal cavities.[14] GRIP1 is also essential for proper function and structure of the dermo-epidermal junction.[15] In mouse models, knocking out GRIP1 protein leads to several deformities that begin in embryo. These deformities include subepidermal hemorrhagic blistering, renal agenesis, syndactylism, polydactylism and cryptopthalmos.[14] One study has shown that complete knock-out of GRIP1 leads to the absence of kidneys.[14] Another study shows blistering of embryonic tissue that GRIP1 is expressed in by day 12 of embryonic life in mice.[15]

The mechanism of GRIP1 in Fraser syndrome is found in the interaction GRIP1 has with the proteins Fras1 and Frem2.[16] Fras1 and Frem2 are extracellular membrane proteins necessary for proper basement membrane function as well as morphogenesis.[16] GRIP1 plays a vital role in localizing Fras1 to the basal surface of epidermal cells as well as localizing Frem2.[16] Knocking out the GRIP1 protein or mutating it leads to poor expression of Fras1 and Frem2.[16] GRIP1 specifically binds with Fras1 through a PDZ motif located on Fras1.[16] Frem2 also has a PDZ domain, although the interaction between GRIP1 and Frem2 is unclear.[16] In one case of Fraser syndrome, GRIP1 lacked PDZ domains 6 and 7. Only the first four PDZ domains of the seven PDZ domains GRIP1 has are required for binding with Fras1, indicating additional mechanisms and proteins GRIP1 interacts with that could lead to Fraser syndrome when mutated.[17] Other mutations in GRIP1 that lead to Fraser syndrome include nonsense mutations, frameshift mutations, splice site mutations, a genome deletion and a deletion of exon 18 of the GRIP1 gene.[13]

Role of GRIP1 in neuron morphology and cargo transport

Neuron morphology, development, and maintenance are dependent on the expression of GRIP1 in the cell.[18] It is vitally important in initial development as knock out experiments in murine models result in skin blisters and embryonic lethality.[15] In developed murine models, disabling mutations like transfecton or dominant negatives in GRIP1 can cause up to 75% loss in “primary, secondary, and higher-order” dendrites in developing neurons.[19] Disabling GRIP1 in live healthy neurons in a dish will cause a 20% reduction in the thickest part of the neuron and up to 70% reduction in the branches.[18]

Defects in neuron morphology due to GRIP1 malfunction can be reserved. One way is to overexpress GRIP1. This leads to increased, but not complete recovery of branching.[18] Another protein, EphB2, which interacts with GRIP1, can be mutated such that a 70-90% recovery of branching is possible. However, overexpression of the wild type leads to a decrease in neuron count.[18]

Motor proteins such as Kinesin (KIF5) are bound to adapter molecules like GRIP1 to move cargo from the Golgi to the extremities of a neuron cell. GRIP1 and KIF5 are very commonly found together due to a good binding affinity (Kd range from 10-20nM[20]). As for how cargo gets to the right place, there has been a hypothesis called the “smart motor”.[21] It is currently thought that the “smart motor” recognizes the difference between axonal (coated with KLC protein) and dendritic (coated with KHC) proteins.[21] The destination is chosen accordingly. Unfortunately, details about the intermediate transporting steps are unknown. However, at the destination the binding of protein 14-3-3 disrupts the interaction between KIF5 and GRIP1.[19] This releases the cargo.

See also

References

  1. ^ a b Dong, H; O'Brien, R; Fung, E; Lanahan, A; Worley, P; Hunganir, R (March 1997). "GRIP: A synaptic PDZ domain-containing protein that interacts with AMPA receptors". Nature. 386 (6622): 279–84. Bibcode:1997Natur.386..279D. doi:10.1038/386279a0. PMID 9069286. S2CID 4361791.
  2. ^ Kornau, Hans-Christian; Schenker, Leslie T.; Kennedy, Mary B.; Seeburg, Peter H. (1995). "Domain interaction between NMDA receptor subunits and the postsynaptic density protein PSD-95". Science. 269 (5231): 1737–1740. Bibcode:1995Sci...269.1737K. doi:10.1126/science.7569905. PMID 7569905.
  3. ^ Ehlers, M. D.; Mammen, A. L.; Lau, L.; Huganir, R. L. (1996). "Synaptic targeting of glutamate receptors". Current Opinion in Cell Biology. 8 (4): 484–489. doi:10.1016/S0955-0674(96)80024-X. PMID 8791455.
  4. ^ a b c d Dong, H; O'Brien, R; Fung, E; Lanahan, A; Worley, P; Hunganir, R (1997). "GRIP: A synaptic PDZ domain-containing protein that interacts with AMPA receptors". Nature. 386 (6622): 279–84. Bibcode:1997Natur.386..279D. doi:10.1038/386279a0. PMID 9069286. S2CID 4361791.
  5. ^ Lee, HJ; Zheng, JJ (2010). "PDZ domains and their binding partners: structure, specificity, and modification". Cell Commun Signal. 8: 8. doi:10.1186/1478-811X-8-8. PMC 2891790. PMID 20509869.
  6. ^ Ehlers, M.; Mammen, A.; Lau, L.; Huganir, R. (1998). "Synaptic targeting of glutamate receptors". Current Opinion in Cell Biology. 8 (4): 484–489. doi:10.1016/S0955-0674(96)80024-X. PMID 8791455.
  7. ^ Xia, J; Zhang, X; Staudinger, J; Huganir, R (January 1999). "Clustering of AMPA receptors by the synaptic PDZ domain-containing protein PICK1". Neuron. 22 (1): 179–87. doi:10.1016/s0896-6273(00)80689-3. PMID 10027300.
  8. ^ a b Braithwaite, S; Xia, H; Malenka, R (2002). "Differential roles for NSF and GRIP/ABP in AMPA receptor cycling". Proceedings of the National Academy of Sciences. 99 (10): 7096–101. Bibcode:2002PNAS...99.7096B. doi:10.1073/pnas.102156099. PMC 124534. PMID 12011465.
  9. ^ Dong, H; Zhang, P; Song, I; Petralia, R; Liao, D; Hunganir, R (15 August 1999). "Characterization of the glutamate receptor-interacting proteins GRIP1 and GRIP2". Journal of Neuroscience. 19 (16): 6930–41. doi:10.1523/JNEUROSCI.19-16-06930.1999. PMC 6782851. PMID 10436050.
  10. ^ Wyszynski, M; Valtschanoff, J; Naisbitt, S; Dunah, A; Kim, E; Standaert, D; et al. (1 August 1999). "Association of AMPA receptors with a subset of glutamate receptor-interacting protein in vivo". Journal of Neuroscience. 19 (15): 6528–37. doi:10.1523/JNEUROSCI.19-15-06528.1999. PMC 6782830. PMID 10414981.
  11. ^ Hanley, L; Henley, J (2010). "Differential roles of GRIP1a and GRIP1b in AMPA receptor trafficking". Neuroscience Letters. 485 (3): 167–72. doi:10.1016/j.neulet.2010.09.003. PMC 3310156. PMID 20837103.
  12. ^ DeSouza, S; Fu, J; States, B; Ziff, E (2002). "Differential palmitoylation directs the AMPA receptor-binding protein ABP to spines or to intracellular clusters". Journal of Neuroscience. 22 (9): 3493–503. doi:10.1523/JNEUROSCI.22-09-03493.2002. PMC 6758378. PMID 11978826.
  13. ^ a b Schanze, D (2014). "Fraser syndrome due to mutations in GRIP1--clinical phenotype in two families and expansion of the mutation spectrum". American Journal of Medical Genetics. 164 (3): 837–840. doi:10.1002/ajmg.a.36343. PMID 24357607. S2CID 11034897.
  14. ^ a b c Takamiya, K.; Kostourou, V.; Adams, S.; Jadeja, S.; Chalepakis, G.; Scambler, P. J.; Adams, R. H. (2004). "A direct functional link between the multi-PDZ domain protein GRIP1 and the fraser syndrome protein Fras1". Nature Genetics. 36 (2): 172–7. doi:10.1038/ng1292. PMID 14730302.
  15. ^ a b c Bladt, F (2002). "Epidermolysis bullosa and embryonic lethality in mice lacking the multi-PDZ domain protein GRIP1". Proceedings of the National Academy of Sciences of the United States of America. 99 (10): 6816–6821. Bibcode:2002PNAS...99.6816B. doi:10.1073/pnas.092130099. PMC 124486. PMID 11983858.
  16. ^ a b c d e f Kiyozumi, D (2006). "Breakdown of the reciprocal stabilization of QBRICK/Frem1, Fras1, and Frem2 at the basement membrane provokes fraser syndrome-like defects". Proceedings of the National Academy of Sciences of the United States of America. 103 (32): 11981–11986. Bibcode:2006PNAS..10311981K. doi:10.1073/pnas.0601011103. PMC 1567684. PMID 16880404.
  17. ^ Vogel, M., Zon, P., Brueton, L., Gijzen, M., Tuil, M., Cox, P., ... Haelst, M. (2012). Mutations in GRIP1 cause Fraser syndrome. Journal of Medical Genetics, 303-306.
  18. ^ a b c d Hoogenraad, Casper (Jun 19, 2005). "GRIP1 controls dendrite morphogenesis by regulating EphB receptor trafficking". Nature Neuroscience. 8 (7): 906–916. doi:10.1038/nn1487. PMID 15965473. S2CID 23686585.
  19. ^ a b Geiger, Julia (Feb 24, 2014). "The GRIP1/14-3-3 Pathway Coordinates Cargo Trafficking and Dendrite Development". Developmental Cell. 28 (4): 381–393. doi:10.1016/j.devcel.2014.01.018. PMID 24576423.
  20. ^ Skoufias, Dimitrios (Jan 14, 1994). "The Carboxyl-terminal Domain of Kinesin Heavy Chain is important for membrane binding". Journal of Biological Chemistry. 269 (2): 1477–1485. doi:10.1016/S0021-9258(17)42281-2. PMID 8288613.
  21. ^ a b Setou, Mitsutoshi (May 2, 2002). "Glutamate-receptor-interacting protein GRIP1 directly steers kinesin to dendrites". Letters to Nature. 417 (6884): 83–87. Bibcode:2002Natur.417...83S. doi:10.1038/nature743. PMID 11986669. S2CID 4400494.

August 20, 2023
glutamate, receptor, interacting, protein, grip, refers, either, family, proteins, that, bind, glutamate, receptor, specifically, grip1, protein, within, this, family, proteins, glutamate, receptor, interacting, protein, grip, family, have, been, shown, intera. Glutamate receptor interacting protein GRIP refers to either a family of proteins that bind to the glutamate receptor or specifically to the GRIP1 protein within this family Proteins in the glutamate receptor interacting protein GRIP family have been shown to interact with GluR2 a common subunit in the AMPA receptor 1 This subunit also interacts with other proteins such as protein interacting with C kinase1 PICK1 and N ethylmaleimide sensitive fusion protein NSF Studies have begun to elucidate its function however much is still to be learned about these proteins Contents 1 Discovery and history of GRIP 1 2 Role of GRIP in AMPAR cycling 3 Role of GRIP1 in Fraser syndrome 4 Role of GRIP1 in neuron morphology and cargo transport 5 See also 6 ReferencesDiscovery and history of GRIP 1 Edit Binding of GRIP1 to AMPA ReceptorsThe discovery of the Glutamate Receptor Interacting Protein GRIP 1 came as a result of the observation that Glutamate Receptors such as the NMDA receptor cluster at synapses 2 Shortly after this observation researchers identified a region on the C terminal region of NMDA receptors called the tSXV motif that has the ability to bind to the PDZ domain of the PSD 95 protein 3 Research on NMDA receptor localization paved the way for research on non NMDA receptors such as AMPA receptors Similar to NMDA receptors it was discovered that AMPA receptors localize in the synaptic terminal of neurons in the central nervous system 4 By using GFP green fluorescent protein antibodies that correspond to the GRIP protein researchers were able to use fluorescence to determine the location of GRIP in hippocampal neurons Another GFP antibody was then used to label the GluR2 subunit of AMPA receptors 4 By using immunocytochemistry and comparing the location of GRIP and AMPA receptors it was determined that GRIP and AMPA receptors experience colocalization in hippocampal neurons 4 These findings confirmed the initial hypothesis that the GRIP protein plays an important role in binding AMPA receptors to excitatory synapses The structure of GRIP contains seven PDZ domains and binds to the C terminus of the GluR2 subunit of AMPA receptors 4 Although the number of PDZ domains is different for the proteins PSD 95 and GRIP the PDZ domain is a common structural motif in proteins that help mediate protein protein interactions 5 The AMPA receptor amino acid sequence that the GRIP protein binds to is ESVKI The conserved serine amino acid in the C terminus of both AMPA and NMDA receptors suggests that it plays an important role in facilitating the interaction for GRIP and PSD 95 6 Role of GRIP in AMPAR cycling EditAMPA receptors are constantly being transported between the cell membrane and intracellular space and it was originally thought that GRIP may be responsible for the clustering of AMPA receptors at the excitatory synapse 1 Although it is still unclear the exact role of GRIP in this trafficking It appears that PICK1 is more directly responsible for the clustering of AMPA receptors at the surface and that GRIP is involved in the stabilization of AMPA receptors intracellularly 7 One study showed that when the interaction between GluR2 and GRIP is disrupted there are no changes in the surface expression of AMPA receptors or the constitutive internalization of AMPA receptors 8 There is however a reduced amount of receptors that remain internalized when receptor cycling is modified by application of AMPA 1 The ratio returns to normal when constitutive recycling is allowed to happen suggesting that the stabilization of intracellular receptors is critical only under AMPA induced internalization 8 Illustration of roles of GRIP1a and GRIP1b in AMPAR cyclingIn later studies two proteins GRIP 1 often reduced to GRIP and ABP L also named GRIP 2 were found to be expressed by two separate genes and their respective contributions to AMPA receptor cycling have since been well studied Each of these proteins have different isoforms due to differential RNA splicing 9 10 The isoforms of GRIP 1 are named GRIP 1a and GRIP 1b while those of ABP L are distinguished as ABP L and pABP L The apparent difference in both cases is that one isoform GRIP1b and pABP L respectively is capable of being conjugated with Palmitic acid an action called Palmitoylation Whereas GRIP initially was thought to be involved in the stabilization of AMPA receptors either at the cell surface or intracellularly when internalization was triggered by AMPA stimulation it now appears that the GRIP 1 isoforms are involved differentially with the stabilization of AMPA receptors after being internalized due to NMDA stimulation 11 GRIP 1a has been shown to reduce the expected intracellular levels of AMPA receptors after NMDA stimulation Conversely GRIP 1b increases intracellular levels of AMPA receptors under the same conditions ABP L like GRIP 1b associates with intracellular stores of AMPA receptors pABP L however associates with AMPA receptors as the surface membrane 12 It has not yet been shown under what conditions these interactions are significant in the cycling of AMPAR Role of GRIP1 in Fraser syndrome Edit This diagram depicts the role GRIP1 plays in localizing extra cellular matrix proteins Fras1 and Frem2 at the dermo epidermal junction Mutations to GRIP1 play a role in less than 10 of confirmed cases of the group of congenital defects known as Fraser syndrome 13 Using immunofluorescence it has been shown that GRIP1 is found in several kinds of embryonic tissues including the GI tract ureter buds skin and oral and nasal cavities 14 GRIP1 is also essential for proper function and structure of the dermo epidermal junction 15 In mouse models knocking out GRIP1 protein leads to several deformities that begin in embryo These deformities include subepidermal hemorrhagic blistering renal agenesis syndactylism polydactylism and cryptopthalmos 14 One study has shown that complete knock out of GRIP1 leads to the absence of kidneys 14 Another study shows blistering of embryonic tissue that GRIP1 is expressed in by day 12 of embryonic life in mice 15 The mechanism of GRIP1 in Fraser syndrome is found in the interaction GRIP1 has with the proteins Fras1 and Frem2 16 Fras1 and Frem2 are extracellular membrane proteins necessary for proper basement membrane function as well as morphogenesis 16 GRIP1 plays a vital role in localizing Fras1 to the basal surface of epidermal cells as well as localizing Frem2 16 Knocking out the GRIP1 protein or mutating it leads to poor expression of Fras1 and Frem2 16 GRIP1 specifically binds with Fras1 through a PDZ motif located on Fras1 16 Frem2 also has a PDZ domain although the interaction between GRIP1 and Frem2 is unclear 16 In one case of Fraser syndrome GRIP1 lacked PDZ domains 6 and 7 Only the first four PDZ domains of the seven PDZ domains GRIP1 has are required for binding with Fras1 indicating additional mechanisms and proteins GRIP1 interacts with that could lead to Fraser syndrome when mutated 17 Other mutations in GRIP1 that lead to Fraser syndrome include nonsense mutations frameshift mutations splice site mutations a genome deletion and a deletion of exon 18 of the GRIP1 gene 13 Role of GRIP1 in neuron morphology and cargo transport EditNeuron morphology development and maintenance are dependent on the expression of GRIP1 in the cell 18 It is vitally important in initial development as knock out experiments in murine models result in skin blisters and embryonic lethality 15 In developed murine models disabling mutations like transfecton or dominant negatives in GRIP1 can cause up to 75 loss in primary secondary and higher order dendrites in developing neurons 19 Disabling GRIP1 in live healthy neurons in a dish will cause a 20 reduction in the thickest part of the neuron and up to 70 reduction in the branches 18 Defects in neuron morphology due to GRIP1 malfunction can be reserved One way is to overexpress GRIP1 This leads to increased but not complete recovery of branching 18 Another protein EphB2 which interacts with GRIP1 can be mutated such that a 70 90 recovery of branching is possible However overexpression of the wild type leads to a decrease in neuron count 18 Motor proteins such as Kinesin KIF5 are bound to adapter molecules like GRIP1 to move cargo from the Golgi to the extremities of a neuron cell GRIP1 and KIF5 are very commonly found together due to a good binding affinity Kd range from 10 20nM 20 As for how cargo gets to the right place there has been a hypothesis called the smart motor 21 It is currently thought that the smart motor recognizes the difference between axonal coated with KLC protein and dendritic coated with KHC proteins 21 The destination is chosen accordingly Unfortunately details about the intermediate transporting steps are unknown However at the destination the binding of protein 14 3 3 disrupts the interaction between KIF5 and GRIP1 19 This releases the cargo See also EditAMPA receptor PICK1 GRIP1 gene GRIP2 Fraser syndrome FRAS1 FREM2References Edit a b Dong H O Brien R Fung E Lanahan A Worley P Hunganir R March 1997 GRIP A synaptic PDZ domain containing protein that interacts with AMPA receptors Nature 386 6622 279 84 Bibcode 1997Natur 386 279D doi 10 1038 386279a0 PMID 9069286 S2CID 4361791 Kornau Hans Christian Schenker Leslie T Kennedy Mary B Seeburg Peter H 1995 Domain interaction between NMDA receptor subunits and the postsynaptic density protein PSD 95 Science 269 5231 1737 1740 Bibcode 1995Sci 269 1737K doi 10 1126 science 7569905 PMID 7569905 Ehlers M D Mammen A L Lau L Huganir R L 1996 Synaptic targeting of glutamate receptors Current Opinion in Cell Biology 8 4 484 489 doi 10 1016 S0955 0674 96 80024 X PMID 8791455 a b c d Dong H O Brien R Fung E Lanahan A Worley P Hunganir R 1997 GRIP A synaptic PDZ domain containing protein that interacts with AMPA receptors Nature 386 6622 279 84 Bibcode 1997Natur 386 279D doi 10 1038 386279a0 PMID 9069286 S2CID 4361791 Lee HJ Zheng JJ 2010 PDZ domains and their binding partners structure specificity and modification Cell Commun Signal 8 8 doi 10 1186 1478 811X 8 8 PMC 2891790 PMID 20509869 Ehlers M Mammen A Lau L Huganir R 1998 Synaptic targeting of glutamate receptors Current Opinion in Cell Biology 8 4 484 489 doi 10 1016 S0955 0674 96 80024 X PMID 8791455 Xia J Zhang X Staudinger J Huganir R January 1999 Clustering of AMPA receptors by the synaptic PDZ domain containing protein PICK1 Neuron 22 1 179 87 doi 10 1016 s0896 6273 00 80689 3 PMID 10027300 a b Braithwaite S Xia H Malenka R 2002 Differential roles for NSF and GRIP ABP in AMPA receptor cycling Proceedings of the National Academy of Sciences 99 10 7096 101 Bibcode 2002PNAS 99 7096B doi 10 1073 pnas 102156099 PMC 124534 PMID 12011465 Dong H Zhang P Song I Petralia R Liao D Hunganir R 15 August 1999 Characterization of the glutamate receptor interacting proteins GRIP1 and GRIP2 Journal of Neuroscience 19 16 6930 41 doi 10 1523 JNEUROSCI 19 16 06930 1999 PMC 6782851 PMID 10436050 Wyszynski M Valtschanoff J Naisbitt S Dunah A Kim E Standaert D et al 1 August 1999 Association of AMPA receptors with a subset of glutamate receptor interacting protein in vivo Journal of Neuroscience 19 15 6528 37 doi 10 1523 JNEUROSCI 19 15 06528 1999 PMC 6782830 PMID 10414981 Hanley L Henley J 2010 Differential roles of GRIP1a and GRIP1b in AMPA receptor trafficking Neuroscience Letters 485 3 167 72 doi 10 1016 j neulet 2010 09 003 PMC 3310156 PMID 20837103 DeSouza S Fu J States B Ziff E 2002 Differential palmitoylation directs the AMPA receptor binding protein ABP to spines or to intracellular clusters Journal of Neuroscience 22 9 3493 503 doi 10 1523 JNEUROSCI 22 09 03493 2002 PMC 6758378 PMID 11978826 a b Schanze D 2014 Fraser syndrome due to mutations in GRIP1 clinical phenotype in two families and expansion of the mutation spectrum American Journal of Medical Genetics 164 3 837 840 doi 10 1002 ajmg a 36343 PMID 24357607 S2CID 11034897 a b c Takamiya K Kostourou V Adams S Jadeja S Chalepakis G Scambler P J Adams R H 2004 A direct functional link between the multi PDZ domain protein GRIP1 and the fraser syndrome protein Fras1 Nature Genetics 36 2 172 7 doi 10 1038 ng1292 PMID 14730302 a b c Bladt F 2002 Epidermolysis bullosa and embryonic lethality in mice lacking the multi PDZ domain protein GRIP1 Proceedings of the National Academy of Sciences of the United States of America 99 10 6816 6821 Bibcode 2002PNAS 99 6816B doi 10 1073 pnas 092130099 PMC 124486 PMID 11983858 a b c d e f Kiyozumi D 2006 Breakdown of the reciprocal stabilization of QBRICK Frem1 Fras1 and Frem2 at the basement membrane provokes fraser syndrome like defects Proceedings of the National Academy of Sciences of the United States of America 103 32 11981 11986 Bibcode 2006PNAS 10311981K doi 10 1073 pnas 0601011103 PMC 1567684 PMID 16880404 Vogel M Zon P Brueton L Gijzen M Tuil M Cox P Haelst M 2012 Mutations in GRIP1 cause Fraser syndrome Journal of Medical Genetics 303 306 a b c d Hoogenraad Casper Jun 19 2005 GRIP1 controls dendrite morphogenesis by regulating EphB receptor trafficking Nature Neuroscience 8 7 906 916 doi 10 1038 nn1487 PMID 15965473 S2CID 23686585 a b Geiger Julia Feb 24 2014 The GRIP1 14 3 3 Pathway Coordinates Cargo Trafficking and Dendrite Development Developmental Cell 28 4 381 393 doi 10 1016 j devcel 2014 01 018 PMID 24576423 Skoufias Dimitrios Jan 14 1994 The Carboxyl terminal Domain of Kinesin Heavy Chain is important for membrane binding Journal of Biological Chemistry 269 2 1477 1485 doi 10 1016 S0021 9258 17 42281 2 PMID 8288613 a b Setou Mitsutoshi May 2 2002 Glutamate receptor interacting protein GRIP1 directly steers kinesin to dendrites Letters to Nature 417 6884 83 87 Bibcode 2002Natur 417 83S doi 10 1038 nature743 PMID 11986669 S2CID 4400494 Retrieved from https en wikipedia org w index php title Glutamate receptor interacting protein amp oldid 1170052879, wikipedia, wiki, book, books, library,

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